DE10029465A1 - Lamp used for work on e.g. building site, includes emergency lighting unit used when mains electricity fails or is switched off - Google Patents

Abstract

An emergency lighting unit (28) is arranged in or on the casing (12), to provide a light source should the mains power fail, or be switched off.

Description

The invention relates to a work lamp.

Work lights are known from practice and show Housing in which at least one working lamp is arranged, which has a network connection with energy is supplied from a power grid. Such lights will be as portable lights especially on construction sites used in rooms where there are no lamps in are installed. To enable a lineup, point work lights known from practice a foot and / or a standing or holding surface.

On construction sites where the work lights mentioned network interruptions often occur, be it through an unintentional triggering of an FI scarf ters during electrical installation work or an overload of the network or due to a conscious shutdown for Ar work on the power grid. In such a situation, Be users of the work lamp, especially in rooms without a Ta sighted or during the winter months after the onset of the Darkness often faces the problem of oriencing yourself in the dark animals. This is a particular situation Working with dangerous machines, on scaffolding or lei t great dangers.

The invention has for its object a working to provide light, which if missing or switched off network is available as a light source.  

This object is achieved according to the invention with the Features of claim 1.

According to the invention is in or at a work lamp arranged an emergency light device with wel cher the work lamp as a light source when missing or switched off power supply used in an emergency lighting operation is cash. By using an Ar according to the invention beitsleuchte become the dangerous situations described above tions effectively avoided as a user of the work light in a room without daylight when suddenly missing the or switched off power grid no longer towards one due torch or a lighter sen, but to avoid accidents on the ares flashlight can use, whose light avoiding of accidents.

According to a preferred embodiment, the emergency light has setting up the work light on a lamp control gear, which has at least one working lamp in the absence or switched off power supply. Such Design not only minimizes construction parts of the work lamp, but also for similar light conditions for work and emergency lighting operation.

In an alternative preferred embodiment of the Er It is provided that the emergency lighting device is a Lamp operating device, which has an emergency light medium in the case of a missing or disconnected network with electricity provided. In such an embodiment there is one great constructive freedom in the design of the work light because not on the necessary for the work light  Parameters for power supply consideration needs to be taken.

The emergency light device is preferably designed such that that it is automatically activated in the event of a power failure. A Be So the user of the work light has no measures take action when the network is missing or switched off Want to avoid darkness. To prevent the Power supply to the emergency lighting device can be exhausted be provided that the emergency lighting device on the network connection switches back when an Ener energy supply is available again.

The emergency light device preferably has a rechargeable one Accumulator device on. Such an accumulator tion permits environmentally friendly operation of the work light because there are no consumables.

When in or on for the rechargeable battery device charging electronics are provided in the light housing Additional equipment for operating the work lamp not necessary so that it can be ensured that the emergency lighting device practically at any time sufficient energy reserve.

According to a preferred embodiment, the charging elec tronics designed so that they are in a work operation of the working light means the accumulator device itself actively charging. Such an arrangement allows one operation of the work lamp. The charging electronics should be designed for a charging process in which a high state of charge of the battery device priority enjoy. That means that under conscious acceptance of a  Wear of the battery device discharges of the batteries accumulator device should be avoided in order not to a network failure with the problem of lack of loading operating time of the emergency lighting device to be confronted.

As an alternative to an emergency lighting device with rechargeable batteries accumulators are provided that the emergency lighting device has a replaceable battery device. A sol che design of the work lamp is particularly at using the work light in situations with skin Figem power failure advantageous because a replaceable Bat Series device after long emergency lighting operation by switching off change of continuation of the work under emergency lighting leaves, whereas an emergency lighting device that excludes Lich has a rechargeable battery device prolonged power failure requires an interruption of work. According to a preferred embodiment, the emergency light has device both a rechargeable battery device as well as a replaceable battery device on where by combining the advantages of both facilities.

Low energy consumption with high luminosity Work lamp is reached when the work lamp is a low voltage gas discharge lamp. At a such configuration, in the case of emergency lighting operation preferably a low-voltage operating device is provided, also minimizes losses in emergency lighting operation, so that with the existing energy a long lasting Emergency lighting operation is possible.

In the event of a power failure using the fiction continue working or dangerous ar being able to finish it has proven to be beneficial  if the luminous flux in emergency lighting operation is 30-50%, preferably 40% of the luminous flux in work mode wearing. The operating values mentioned represent an advantage adhere to compromise in terms of luminosity and loading operating time of the work lamp in emergency lighting mode. This applies especially if the illuminant is a gas discharge illuminant with 36 watts and the emergency light device has a 6 V 1.2 Ah power supply.

The work lamp can be trained because it can be moved det is used in emergency lighting as a portable light to leave a room in which the network has failed. So it can be used in particular be looking for junction and / or fuse boxes to to restore the power supply via the network. In In such a situation, it is advantageous if the network devices on the housing of the work light plug socket for a with a clamp base Has power cord. Cable wrench, as is often the case Construction sites occur, with such a hinder not taking the work light with you. The ar beitsleuchte is therefore immediately in the event of a power failure available and valuable minutes can be saved become what not only leads to higher labor productivity leads, but can even be life-saving in the event of fire.

Further advantageous refinements and developments the invention emerge from the subclaims and from the description in connection with the drawings.  

Show it:

Fig. 1 is a work lamp according to the invention in simplified ter perspective view,

Fig. 2 is a simplified circuit diagram of a first embodiment of a power supply for the work lamp shown in FIG. 1 with electronic ballast, the lamp being designed as a gas discharge lamp and for the emergency light device which has a DC voltage supply device with emergency light electronics, a switch position the power supply is queried by the emergency lighting electronics,

Fig. 3, provided in the power supply of FIG. 2 DC power supply device in detail profiled representation,

Fig. 4 is a simplified circuit diagram of a second embodiment of a power supply of the work lamp shown in Fig. 1 ge, wherein a magnetic ballast is provided, and

Fig. 5 is a graph for the charging current of charging electronics for temporary operation on the network.

The work lamp 10 shown in FIG. 1 has a housing 12 which is divided into a body 14 and a front pane 16 . The front screen 16 , which has three perpendicular webs (not shown) for stabilization, is matted in its lower region for aesthetic reasons. The front pane 16 is crystal clear in its upper region. The front screen 16 is made of polycarbonate.

The body 14 is made as a two-component injection molded part with the dimensions W / H / D = 300 mm / 320 mm / 115 mm, a trough-like, rear part 18 of the body 14 consisting of dark, preferably blue-colored polycarbonate, on which faces the windshield 16 out a rubber-like holding and sealing part 20 connects in one piece. The gummy holding and sealing portion 20 of the body 14 is such bieg executed sam that the front wheel can be fitted into these 16, wherein the holding and sealing portion 20 of the Cor pus 14 simultaneously acts as a seal for the windscreen sixteenth The holding and sealing portion 20 of the body 14 is a bead on the plane of the front plate 16 out to a drop in the task light 10, a Beschädi account the faceplate 16 to prevent. Without sockets, the work light has protection class II and a degree of protection IP54 according to VDE, with sockets protection class I and a degree of protection IP44.

On the back of the body 14 are in addition to a lockable in ver different locking positions for different light emission directions, usable as a handle 22 sockets (not shown) and a cable bushing (not shown) for the trained as a rubber connecting cord power cord 24 are provided. The handle / foot 22 , which is made of ABS, allows the work light 10 to be mounted on a tripod. The power cord is, since no connector is provided, in the course of the axis of rotation of the handle / foot 22 leads into the housing 12 ge. The underside of the body 14 is designed as a base.

Inside the body 14 of the work lamp 10 , a reflector 26 made of vapor-coated plastic material and a Arbeitsleuchtmit tel 28 are arranged in addition to the facilities for the power supply. The working light source is a TC-F compact tube with 36 watt power consumption in a single base. A TC-F compact tube delivers a luminous flux of 2800 Im. Alternatively, the work lamp can be designed with a base for two TC-F compact tubes, each with a power consumption of 36 watts.

A switch 34 for operating the power supply of the Ar beitsleuchtmittels 28 allows to turn off the work of lamps 28 and to use the task light 10 as a distributor.

The circuit diagram shown in FIG. 2 for a first embodiment of the power supply of the working lamp 10 shown in FIG. 1 shows an AC power supply device 30 which is connected via a terminal base 32 and the power cable 24 to a 230 V AC supply network. To turn on the AC power supply, a power switch 34 is provided, which is provided on the housing 12 of the work lamp 10 for manual operation. On the output side is the AC voltage power supply device 30 , which contains an electronic ballast via a four-pole line 36 and a supply device 38 , A provided on a direct current power supply switch 40, connected to the working light source 28 . On the output side, contrast-selspannungsenergieversorgungsgerät 30 a working voltage of approximately 100 V as well as corresponding a starting voltage, wherein the alternating voltage power supply apparatus of the working luminous means 28 has a warm start allowed 30 by a preheating of the electrodes.

The DC power supply 38, which is shown in Fig. 3 in detail, comprises a rechargeable battery mulatoreinrichtung 42 which and the switch 40 is switchable via a voltage ler wall 44 to the working light-emitting means 28. The voltage converter 44 converts the direct current supplied by the rechargeable battery device 42 , which is designed as a 6 V 1.2 Ah NiCd battery, approximately 80-100 into 130 V lamp operating voltage. The rechargeable accumulator device 42 is designed as a high-temperature accumulator device and allows a permanent thermal load of 40 ° C. to 70 ° C., in particular 65 ° C. With this accumulator device, an emergency light operation for 20-30 minutes is in the described work lamp. possible. The DC voltage power supply device 38 , the accumulator device 42 and the working light source 28 together form the emergency light device.

The rechargeable battery device can be charged via a network part 46 and a charger 48 , where the power supply 46 is connected via its inputs L and N to the power cord 24 .

In order to control the power supply of the working light source 28 , the charging operation of the rechargeable battery device 42 and, if necessary, an emergency light operation of the working light source 28 , control electronics 50 are provided, which have an output 52 for switching between working operation and emergency light operation via the switch 40 . From the output 52 controls a switching transistor 54 which controls the operating current of the switch 40 designed as a relay. The operating current for the switch 40 is supplied by the rechargeable battery device 42 .

Furthermore, the control electronics 50 has an output 56 , via which the voltage converter 44 is switched on or off.

In order to determine whether the power supply system is able to supply the working light bulb 28 during operation, an input 60 is provided on the control electronics 50 , via which an input voltage representing the network is supplied to the control electronics 50 . A diode 62 provided in the charging device 48 prevents, in addition to discharging the rechargeable battery device 42 , also an incorrect evaluation of the voltage states. The Ladeeinrich device 48 and the control electronics 50 together form the charging electronics.

Since the power supply unit 46 is permanently connected to the power supply when the work lamp 10 is inserted, the control electronics 50 has a second input 64 , via which the switch position of the power switch 34 is queried. When the power switch 34 is closed, not only is the alternating voltage power supply device 30 supplied with voltage but also via a resistor 66 , a light-emitting diode 68 of an optical coupler 70 , the photocell 72 of which via the second input 64 in the case of a closed switch position of the power switch 34 to the control electronics 50 provides a signal. Is the power switch 34 closed ge and is due to a missing network at the input 60 no reference voltage to the control electronics 50 switches the switch 40 to emergency lighting, so that the energy provided by the rechargeable battery device 42 via the voltage converter 44 to the working light source 28 Available. The start of the work lamp 28 in emergency lighting operation is according to the power supply in FIGS . 2 and 3 out as a cold start.

In addition to switching the work lamp 10 between work mode and emergency light mode, the control electronics 50 controls the charging of the rechargeable battery device 42 . For this purpose, a battery voltage input 74 is provided on the control electronics 50 . If the battery voltage is below a given target value, a charging transistor 76 is enabled via the output 78 of the control electronics. One of the control electronics 50 addressed in the case of charging operation charging LED 80 allows control of the charging process and thus the state of charge of the rechargeable battery accumulator 42nd

The second embodiment shown in FIG. 4 of a power supply of the work lamp shown in FIG. 1 differs from the power supply according to the first embodiment shown in FIGS. 2 and 3 only with regard to the AC power supply. For elements of the power supply according to the second embodiment in FIG. 4, the elements of the power supply according to the first embodiment in FIGS . 2 and 3 correspond, reference numerals are therefore used, which are increased by a 100 over the first embodiment. Reference is made to the description of the corresponding parts.

In Fig. 4, an AC power supply device 190 is provided for working, which has a star ter 192 and an inductor 194 . It can be clearly seen that the line 136 led to the working light source 128 via the switch 140 is designed with four poles, a warm start also being provided for the working mode and a cold start for the emergency light mode in the power supply according to FIG. 4.

In Fig. 5 is an example of a charging current waveform at times chosen range operation of the task light 10 on the network, which is executed by the control electronics 50, shown with the charging current I is plotted over time t. In Fig. 5, I _{S denotes} a high standard charging current and I _E an underlying trickle charging current. The rechargeable accumulator device 42 is discharged at the beginning of the course shown in FIG. 5.

If, at time t _1, the work lamp 10 is connected to the discharging accumulator device 42 by connecting the mains connection cable to the mains, the control electronics detects the insufficient state of charge of the accumulator device 42 and switches the charging device 48 to the standard charging current. If at the time the task light 10 t ₂ separated from the mains or falls at the time t ₂ from the network, charging of the rechargeable accumulator 42 is interrupted. If the mains voltage is available again at time t ₃ , the charging process is continued with the standard charging current I _S until time t ₄ , at which the mains connection is interrupted again. At time t ₅ , the charging process is continued with the high standard charging current as in time t ₃ when the battery device is in an insufficient state of charge until a sufficient state of charge is reached at time t ₆ . A standard load always occurs when the load is below 70%, preferably below 80% of the maximum landing. At this point in time t ₆ , the control electronics 50 switches to a trickle charge current I _E which is below the standard charging current until a mains interruption occurs at point in time t ₇ . If the network is available again at time t ₈ and emergency lighting operation has not taken place between times t ₇ and t ₈ , control electronics 50 switches to the high standard charging current I _S only for a few minutes in order to switch back to trickle charging current I _E at time t ₉ , This type of charging of the accumulator device 42 achieves an optimal state of charge in a short time even when the power supply is interrupted, overcharging being avoided. The requirements for emergency lighting operation and in terms of service life are optimally balanced.

Claims (16)

1. work light, with a base ( 22 ) and / or a stand or holding surface provided with a housing ( 12 ), at least one in the housing ( 12 ) provided work lamps ( 28 ) for a work operation and with a mains connection, in order to supply at least one work light means ( 28 ) with energy from a power supply during operation, characterized by an emergency light device ( 38 , 42 , 28 ) arranged in or on the housing ( 12 ), with which the work light ( 10 ) as Light source can be used in an emergency lighting mode when the network is missing or switched off. 2. Work light according to claim 1, characterized in that the emergency light device ( 38 , 42 , 28 ) has a power supply which supplies at least one of the work light means ( 28 ) with a missing or switched off network. 3. Work lamp according to claim 1, characterized in that the emergency lighting device has a power supply which has an emergency light bulb in the absence or switched off power supply. 4. Work lamp according to one of claims 1 to 3, characterized in that the emergency light device ( 38 , 42 , 28 ) is automatically activated in the event of a power failure. 5. Work lamp according to one of claims 1 to 4, characterized in that the emergency light device ( 38 , 42 , 28 ) has a rechargeable battery device ( 42 ). 6. Work lamp according to claim 5, characterized in that for the rechargeable battery device ( 42 ) in or on the lamp housing ( 12 ), charging electronics ( 48 , 50 ) is provided. 7. Work lamp according to claim 6, characterized in that the charging electronics ( 48 , 50 ) automatically charges the rechargeable battery device ( 42 ) when the work lamp ( 28 ) is in operation. 8. Work lamp according to claim 7, characterized in that the charging electronics ( 48 , 50 ) carries out a charging process in which a high state of charge of the battery device ( 42 ) enjoys priority. 9. Work lamp according to one of claims 4 to 8, characterized in that the emergency light device ( 38 , 42 , 28 ) interrogates a switching element ( 34 ) in order to distinguish between a mains interruption and a switching off of the work lamp ( 28 ). 10. Work lamp according to claim 9, characterized in that the switching element is a main path for switching the Working current and a secondary path for evaluating the Has switching state. 11. Work lamp according to claim 9, characterized in that the switching element has two measuring outputs or an electronic query, in particular with at least one inductive, capacitive or optical coupler ( 70 ) to detect a mains voltage. 12. Work lamp according to one of claims 1 to 4, characterized characterized in that the emergency lighting device a interchangeable battery device. 13. Work lamp according to one of claims 1 to 12, characterized in that the working lamp Low voltage gas discharge lamp is, and that for Operation of the work lamp in the work mode Mains voltage operating device is present. 14. Work lamp according to claim 13, characterized in that to operate the work light in Emergency lighting operation is a low voltage control gear is provided. 15. Work lamp according to one of claims 1 to 14, characterized in that the luminous flux in Emergency lighting operation 30% to 50%, preferably 40% of the Luminous flux in work mode. 16. Work lamp according to one of claims 1 to 15, characterized in that the mains connection on the housing ( 12 ) has a device plug socket and a power cable provided with a device plug ( 24 ).